Cellular mobile telephone terminal

1. A cellular mobile telephone terminal comprising a baseband section ( 101 ) for processing a voice signal and a radio transceiver section ( 210 ) for taking as an input the voice signal processed by said baseband section ( 101 ) and for performing communications with a base station, wherein said radio transceiver section ( 201 ) comprises a transmitter section ( 250 ) for generating a signal for transmission to said base station and a receiver section ( 220 ) for receiving a signal transmitted from said base station, said transmitter section ( 250 ) comprising an intermediate frequency section ( 260 ) for performing heterodyning for modulation and frequency conversion of the voice signal supplied from said baseband section ( 101 ) and a radio frequency section ( 270 ) for amplifying a radio frequency signal output from said intermediate frequency section ( 260 ) and for supplying said amplified signal to an antenna, said radio frequency section ( 270 ) comprising a gain controller ( 271 ) for controlling the gain of said radio frequency signal output from said intermediate frequency section ( 260 ) and a power amplifier ( 242 ) for amplifying the power of an output of said gain controller ( 271 ), and wherein: said baseband section ( 101 ) includes a control section, and said control section detects the output level of said power amplifier ( 242 ) while also detecting signal strength of the signal received by said receiver section ( 220 ), sets an output level target value for said power amplifier ( 242 ) based on the signal strength of said received signal, compares the output level of said power amplifier ( 242 ) with said output level target value of said power amplifier ( 242 ), and applies to said gain controller ( 271 ) a gain control voltage responsive to the result of said comparison, thereby controlling the gain of said gain controller ( 271 ) in a feedback loop so that the output level of said power amplifier ( 242 ) matches said output level target value of said power amplifier ( 242 ); and said gain controller ( 271 ) comprises: a signal line ( 55 ) containing at least two series variable resistors ( 51 ) and ( 52 ) and connecting between a signal input part ( 34 ) and signal output part ( 35 ) for said radio frequency signal; and parallel variable resistors ( 53 ) and ( 54 ) connected between a groundline ( 57 ) and said signal input part ( 34 ) and signal output part ( 35 ), respectively, wherein said gain controller ( 271 ) controls the output of said power amplifier ( 242 ) linearly and in substantially continuous fashion by controlling the gain of each of said variable resistors ( 51 ), ( 52 ), ( 53 ), and ( 54 ) through said gain control voltage which is applied to a gain control voltage application part ( 19 ).

2. A cellular mobile telephone terminal comprising a baseband section ( 101 ) for processing a voice signal and a radio transceiver section ( 210 ) for taking as an input the voice signal processed by said baseband section ( 101 ) and for performing communications with a base station, wherein said radio transceiver section ( 201 ) comprises a transmitter section ( 250 ) for generating a signal for transmission to said base station and a receiver section ( 220 ) for receiving a signal transmitted from said base station, said transmitter section ( 250 ) comprising an intermediate frequency section ( 260 ) for performing heterodyning for modulation and frequency conversion of the voice signal supplied from said baseband section ( 101 ) and a radio frequency section ( 270 ) for amplifying a radio frequency signal output from said intermediate frequency section ( 260 ) and for supplying said amplified signal to an antenna, said radio frequency section ( 270 ) comprising a gain controller ( 271 ) for controlling the gain of said radio frequency signal output from said intermediate frequency section ( 260 ) and a power amplifier ( 242 ) for amplifying the power of an output of said gain controller ( 271 ), and wherein: said baseband section ( 101 ) includes a control section, and said control section detects the output level of said power amplifier ( 242 ) while also detecting signal strength of the signal received by said receiver section ( 220 ), sets an output level target value for said power amplifier ( 242 ) based on the signal strength of said received signal, compares the output level of said power amplifier ( 242 ) with said output level target value of said power amplifier ( 242 ), and applies to said gain controller ( 271 ) a gain control voltage responsive to the result of said comparison, thereby controlling the gain of said gain controller ( 271 ) in a feedback loop so that the output level of said power amplifier ( 242 ) matches said output level target value of said power amplifier ( 242 ); and said gain controller ( 271 ) comprises: a signal line ( 55 ) containing at least two series variable resistors ( 51 ) and ( 52 ) and connecting between a signal input part ( 34 ) and signal output part ( 35 ) for said radio frequency signal; parallel variable resistors ( 53 ) and ( 54 ) connected between a ground line ( 57 ) and said signal input part ( 34 ) and signal output part ( 35 ), respectively; a gain control line ( 56 ) connected to said variable resistors ( 51 ), ( 52 ), ( 53 ), and ( 54 ); reference voltage application parts ( 23 ), ( 27 ), ( 31 ), and ( 33 ) connected to said variable resistors ( 51 ), ( 52 ), ( 53 ), and ( 54 ), respectively; and a gain control voltage application part ( 19 ) connected to each of said variable resistors ( 51 ), ( 52 ), ( 53 ), and ( 54 ) via said gain control line ( 56 ) for application of said gain control voltage.

3. A cellular mobile telephone terminal according to claim 2 , wherein said variable resistors ( 51 ), ( 52 ), ( 53 ), and ( 54 ) are formed at least from field effect transistors ( 21 ), ( 25 ), ( 16 ), and ( 28 ) whose gates are connected to resistors ( 22 ), ( 26 ), ( 20 ), and ( 32 ), respectively, and wherein: the gates of said field effect transistors ( 21 ) and ( 25 ) forming said variable resistors ( 51 ) and ( 52 ) are connected to said gain control voltage application part ( 19 ) via said resistors ( 22 ) and ( 26 ), respectively, and via said gain control line ( 56 ); the gates of said field effect transistors ( 16 ) and ( 28 ) forming said variable resistors ( 53 ) and ( 54 ) are connected to said reference voltage application parts ( 31 ) and ( 33 ) via said resistors ( 20 ) and ( 32 ), respectively; the sources of said field effect transistors ( 21 ) and ( 25 ) forming said variable resistors ( 51 ) and ( 52 ) are connected to said reference voltage application parts ( 23 ) and ( 27 ), respectively, said variable resistors ( 51 ) and ( 52 ) being connected in series via a capacitor ( 24 ); the sources of said field effect transistors ( 16 ) and ( 28 ) forming said variable resistors ( 53 ) and ( 54 ) are connected to said gain control voltage application part ( 19 ) via said gain control line ( 56 ); the drains of said field effect transistors ( 16 ) and ( 28 ) forming said variable resistors ( 53 ) and ( 54 ) are connected via capacitors ( 17 ) and ( 29 ) to said signal input part ( 34 ) and said signal output part ( 35 ), respectively; and the sources of said field effect transistors ( 16 ) and ( 28 ) forming said variable resistors ( 53 ) and ( 54 ) are connected to a base potential part (GND) via capacitors ( 18 ) and ( 30 ), respectively, and via said ground line ( 57 ).

4. A cellular mobile telephone terminal according to claim 2 , wherein a voltage applied to said reference voltage application part ( 23 ) is higher than a voltage applied to said reference voltage application part ( 27 ).

5. A cellular mobile telephone terminal according to claim 2 , wherein a voltage applied to said reference voltage application part ( 23 ) is higher than a voltage applied to said reference voltage application part ( 27 ) by a value corresponding to a gain control voltage range where said variable resistor ( 52 ) performs a linear gain control operation.

6. A cellular mobile telephone terminal according to claim 2 , wherein the values of voltages applied to said reference voltage application parts ( 31 ) and ( 33 ) are set so that a gain control voltage range where said variable resistors ( 53 ) and ( 54 ) perform a linear gain control operation becomes continuous with a gain control voltage range where said variable resistors ( 51 ) and ( 52 ) perform a linear gain control operation.

7. A cellular mobile telephone terminal according to claim 2 , wherein said variable resistors ( 51 ), ( 52 ), ( 53 ), and ( 54 ) are formed at least from field effect transistors ( 21 ), ( 25 ), ( 16 ), and ( 28 ) whose gates are connected to resistors ( 22 ), ( 26 ), ( 20 ), and ( 32 ), respectively, and wherein: the gates of said field effect transistors ( 21 ) and ( 25 ) forming said variable resistors ( 51 ) and ( 52 ) are connected to said gain control voltage application part ( 19 ) via said resistors ( 22 ) and ( 26 ), respectively, and via said gain control line ( 56 ); the gates of said field effect transistors ( 16 ) and ( 28 ) forming said variable resistors ( 53 ) and ( 54 ) are connected together via said resistors ( 20 ) and ( 32 ); a resistor ( 38 ) is inserted between the sources of said field effect transistors ( 21 ) and ( 25 ) forming said variable resistors ( 51 ) and ( 52 ); a resistor ( 39 ) is inserted between the source of said field effect transistor ( 25 ) forming said variable resistor ( 52 ) and a part ( 61 ) connected via said resistors ( 20 ) and ( 32 ) to the gates of said field effect transistors ( 16 ) and ( 28 ) forming said variable resistors ( 53 ) and ( 54 ); a resistor ( 40 ) is inserted between a base potential part (GND) and said part ( 61 ) connected via said resistors ( 20 ) and ( 32 ) to the gates of said field effect transistors ( 16 ) and ( 28 ) forming said variable resistors ( 53 ) and ( 54 ); said reference voltage application part ( 23 ) is connected to the source of said field effect transistor ( 21 ) forming said variable resistor ( 51 ); said variable resistors ( 51 ) and ( 52 ) are connected in series via a capacitor ( 24 ); the sources of said field effect transistors ( 16 ) and ( 28 ) forming said variable resistors ( 53 ) and ( 54 ) are connected to said gain control voltage application part ( 19 ) via said gain control line ( 56 ); the drains of said field effect transistors ( 16 ) and ( 28 ) forming said variable resistors ( 53 ) and ( 54 ) are connected via capacitors ( 17 ) and ( 29 ) to said signal input part ( 34 ) and said signal output part ( 35 ), respectively; and the sources of said field effect transistors ( 16 ) and ( 28 ) forming said variable resistors ( 53 ) and ( 54 ) are connected to said base potential part (GND) via capacitors ( 18 ) and ( 30 ), respectively, and via said ground line ( 57 ).

8. A cellular mobile telephone terminal comprising a baseband section ( 101 ) for processing a voice signal and a radio transceiver section ( 210 ) for taking as an input the voice signal processed by said baseband section ( 101 ) and for performing communications with a base station, wherein said radio transceiver section ( 201 ) comprises a transmitter section ( 250 ) for generating a signal for transmission to said base station and a receiver section ( 220 ) for receiving a signal transmitted from said base station, said transmitter section ( 250 ) comprising an intermediate frequency section ( 260 ) for performing heterodyning for modulation and frequency conversion of the voice signal supplied from said baseband section ( 101 ) and a radio frequency section ( 270 ) for amplifying a radio frequency signal output from said intermediate frequency section ( 260 ) and for supplying said amplified signal to an antenna, said radio frequency section ( 270 ) comprising a gain controller ( 271 ) for controlling the gain of said radio frequency signal output from said intermediate frequency section ( 260 ) and a power amplifier ( 242 ) for amplifying the power of an output of said gain controller ( 271 ), and wherein: said baseband section ( 101 ) includes a control section, and said control section detects the output level of said power amplifier ( 242 ) while also detecting signal strength of the signal received by said receiver section ( 220 ), sets an output level target value for said power amplifier ( 242 ) based on the signal strength of said received signal, compares the output level of said power amplifier ( 242 ) with said output level target value of said power amplifier ( 242 ), and applies to said gain controller ( 271 ) first and second gain control voltages responsive to the result of said comparison, thereby controlling the gain of said gain controller ( 271 ) in a feedback loop so that the output level of said power amplifier ( 242 ) matches said output level target value of said power amplifier ( 242 ); and said gain controller ( 271 ) comprises: a signal line ( 55 ) containing at least two series variable resistors ( 51 ) and ( 52 ) and connecting between a signal input part ( 34 ) and signal output part ( 35 ) for said radio frequency signal; parallel variable resistors ( 53 ) and ( 54 ) connected between a ground line ( 57 ) and said signal input part ( 34 ) and signal output part ( 35 ), respectively; a first gain control line ( 58 ) connected to said variable resistor ( 51 ); a gain control voltage application part ( 42 ) connected to said variable resistor ( 51 ) via said first gain control line ( 58 ) for application of said first gain control voltage; a second gain control line ( 59 ) connected to said variable resistors ( 52 ), ( 53 ), and ( 54 ); a gain control voltage application part ( 19 ) connected to said variable resistors ( 52 ), ( 53 ), and ( 54 ) via said second gain control line ( 59 ) for application of said second gain control voltage; a reference voltage application part ( 23 ) connected to said variable resistors ( 51 ) and ( 52 ); and reference voltage application parts ( 31 ) and ( 33 ) connected to said variable resistors ( 53 ) and ( 54 ), respectively.

9. A cellular mobile telephone terminal according to claim 8 , wherein said variable resistors ( 51 ), ( 52 ), ( 53 ), and ( 54 ) are formed at least from field effect transistors ( 21 ), ( 25 ), ( 16 ), and ( 28 ) whose gates are connected to resistors ( 22 ), ( 26 ), ( 20 ), and ( 32 ), respectively, and wherein: the gate of said field effect transistor ( 21 ) forming said variable resistor ( 51 ) is connected to said gain control voltage application part ( 42 ) via said resistor ( 22 ) and via said first gain control line ( 58 ); the gate of said field effect transistor ( 25 ) forming said variable resistor ( 52 ) is connected to said gain control voltage application part ( 19 ) via said resistor ( 26 ) and via said second gain control line ( 59 ); the gates of said field effect transistors ( 16 ) and ( 28 ) forming said variable resistors ( 53 ) and ( 54 ) are connected to said reference voltage application parts ( 31 ) and ( 33 ) via said resistors ( 20 ) and ( 32 ), respectively; a resistor ( 41 ) is inserted between the sources of said field effect transistors ( 21 ) and ( 25 ) forming said variable resistors ( 51 ) and ( 52 ); the source of said variable resistor ( 52 ) is connected to said reference voltage application part ( 23 ); said variable resistors ( 51 ) and ( 52 ) are connected in series via a capacitor ( 24 ); the sources of said field effect transistors ( 16 ) and ( 28 ) forming said variable resistors ( 53 ) and ( 54 ) are connected to said gain control voltage application part ( 19 ) via said second gain control line ( 59 ); the drains of said field effect transistors ( 16 ) and ( 28 ) forming said variable resistors ( 53 ) and ( 54 ) are connected via capacitors ( 17 ) and ( 29 ) to said signal input part ( 34 ) and said signal output part ( 35 ), respectively; and the sources of said field effect transistors ( 16 ) and ( 28 ) forming said variable resistors ( 53 ) and ( 54 ) are connected to said base potential part (GND) via capacitors ( 18 ) and ( 30 ), respectively, and via said ground line ( 57 ).

10. A cellular mobile telephone terminal according to claim 8 , wherein a voltage applied to said gain control voltage application part ( 19 ) is higher than a voltage applied to said gain control voltage application part ( 42 ).

11. A cellular mobile telephone terminal according to claim 8 , wherein a voltage applied to said gain control voltage application part ( 19 ) is higher than a voltage applied to said gain control voltage application part ( 42 ) by a value corresponding to a gain control voltage range where said variable resistor ( 52 ) performs a linear gain control operation.

12. A cellular mobile telephone terminal according to claim 8 , wherein the values of voltages applied to said reference voltage application parts ( 31 ) and ( 33 ) are set so that a gain control voltage range where said variable resistors ( 53 ) and ( 54 ) perform a linear gain control operation becomes continuous with a gain control voltage range where said variable resistors ( 51 ) and ( 52 ) perform a linear gain control operation.

13. A cellular mobile telephone terminal according to claim 8 , wherein said variable resistors ( 51 ), ( 52 ), ( 53 ), and ( 54 ) are formed at least from field effect transistors ( 21 ), ( 25 ), ( 16 ), and ( 28 ) whose gates are connected to resistors ( 22 ), ( 26 ), ( 20 ), and ( 32 ), respectively, and wherein: the gate of said field effect transistor ( 21 ) forming said variable resistor ( 51 ) is connected to said gain control voltage application part ( 42 ) via said resistor ( 22 ) and via said first gain control line ( 58 ); the gate of said field effect transistor ( 25 ) forming said variable resistor ( 52 ) is connected to said gain control voltage application part ( 19 ) via said resistor ( 26 ) and via said second gain control line ( 59 ); the gates of said field effect transistors ( 16 ) and ( 28 ) forming said variable resistors ( 53 ) and ( 54 ) are connected together via said resistors ( 20 ) and ( 32 ); a resistor ( 41 ) is inserted between the sources of said field effect transistors ( 21 ) and ( 25 ) forming said variable resistors ( 51 ) and ( 52 ); a resistor ( 39 ) is inserted between the source of said field effect transistor ( 25 ) forming said variable resistor ( 52 ) and a part ( 61 ) connected via said resistors ( 20 ) and ( 32 ) to the gates of said field effect transistors ( 16 ) and ( 28 ) forming said variable resistors ( 53 ) and ( 54 ); a resistor ( 40 ) is inserted between a base potential part (GND) and said part ( 61 ) connected via said resistors ( 20 ) and ( 32 ) to the gates of said field effect transistors ( 16 ) and ( 28 ) forming said variable resistors ( 53 ) and ( 54 ); said reference voltage application part ( 23 ) is connected to the source of said field effect transistor ( 25 ) forming said variable resistor ( 52 ); said variable resistors ( 51 ) and ( 52 ) are connected in series via a capacitor ( 24 ); the sources of said field effect transistors ( 16 ) and ( 28 ) forming said variable resistors ( 53 ) and ( 54 ) are connected to said gain control voltage application part ( 19 ) via said second gain control line ( 59 ); the drains of said field effect transistors ( 16 ) and ( 28 ) forming said variable resistors ( 53 ) and ( 54 ) are connected via capacitors ( 17 ) and ( 29 ) to said signal input part ( 34 ) and said signal output part ( 35 ), respectively; and the sources of said field effect transistors ( 16 ) and ( 28 ) forming said variable resistors ( 53 ) and ( 54 ) are connected to said base potential part (GND) via capacitors ( 18 ) and ( 30 ), respectively, and via said ground line ( 57 ).

14. A cellular mobile telephone terminal comprising a baseband section ( 101 ) for processing a voice signal and a radio transceiver section ( 210 ) for taking as an input the voice signal processed by said baseband section ( 101 ) and for performing communications with a base station, wherein said radio transceiver section ( 201 ) comprises a transmitter section ( 250 ) for generating a signal for transmission to said base station and a receiver section ( 220 ) for receiving a signal transmitted from said base station, said transmitter section ( 250 ) comprising an intermediate frequency section ( 260 ) for performing heterodyning for modulation and frequency conversion of the voice signal supplied from said baseband section ( 101 ) and a radio frequency section ( 270 ) for amplifying a radio frequency signal output from said intermediate frequency section ( 260 ) and for supplying said amplified signal to an antenna, said radio frequency section ( 270 ) comprising a gain controller ( 271 ) for controlling the gain of said radio frequency signal output from said intermediate frequency section ( 260 ) and a power amplifier ( 242 ) for amplifying the power of an output of said gain controller ( 271 ), and wherein: said baseband section ( 101 ) includes a control section, and said control section detects the output level of said power amplifier ( 242 ) while also detecting signal strength of the signal received by said receiver section ( 220 ), sets an output level target value for said power amplifier ( 242 ) based on the signal strength of said received signal, compares the output level of said power amplifier ( 242 ) with said output level target value of said power amplifier ( 242 ), and applies to said gain controller ( 271 ) a gain control voltage responsive to the result of said comparison, thereby controlling the gain of said gain controller ( 271 ) in a feedback loop so that the output level of said power amplifier ( 242 ) matches said output level target value of said power amplifier ( 242 ); and said gain controller ( 271 ) comprises: a signal line ( 55 ) containing at least two series variable resistors ( 51 ) and ( 52 ) and connecting between a signal input part ( 34 ) and signal output part ( 35 ) for said radio frequency signal; parallel variable resistors ( 53 ) and ( 54 ) connected between aground line ( 57 ) and said signal input part ( 34 ) and signal output part ( 35 ), respectively; a gain control line ( 56 ) connecting between said variable resistors ( 51 ), ( 52 ), ( 53 ), and ( 54 ); a gain control voltage application part ( 19 ) connected to said variable resistors ( 51 ), ( 52 ), ( 53 ), and ( 54 ) via said gain control line ( 56 ) for application of said gain control voltage; a reference voltage application part ( 23 ) connected to said variable resistors ( 51 ) and ( 52 ); and reference voltage application parts ( 31 ) and ( 33 ) connected to said variable resistors ( 53 ) and ( 54 ), respectively.

15. A cellular mobile telephone terminal according to claim 14 , wherein said variable resistors ( 51 ), ( 52 ), ( 53 ), and ( 54 ) are formed at least from field effect transistors ( 21 ), ( 25 ), ( 16 ), and ( 28 ) whose gates are connected to resistors ( 22 ), ( 26 ), ( 20 ), and ( 32 ), respectively, and wherein: the gates of said field effect transistors ( 21 ) and ( 25 ) forming said variable resistors ( 51 ) and ( 52 ) are connected to said gain control voltage application part ( 19 ) via said resistors ( 22 ) and ( 26 ), respectively, and via said gain control line ( 56 ); the gates of said field effect transistors ( 16 ) and ( 28 ) forming said variable resistors ( 53 ) and ( 54 ) are connected to said reference voltage application parts ( 31 ) and ( 33 ) via said resistors ( 20 ) and ( 32 ), respectively; a resistor ( 41 ) is inserted between the sources of said field effect transistors ( 21 ) and ( 25 ) forming said variable resistors ( 51 ) and ( 52 ); said reference voltage application part ( 23 ) is connected to the source of said variable resistor ( 52 ); said variable resistors ( 51 ) and ( 52 ) are connected in series via a capacitor ( 24 ); the sources of said field effect transistors ( 16 ) and ( 28 ) forming said variable resistors ( 53 ) and ( 54 ) are connected to said gain control voltage application part ( 19 ) via said gain control line ( 56 ); the drains of said field effect transistors ( 16 ) and ( 28 ) forming said variable resistors ( 53 ) and ( 54 ) are connected via capacitors ( 17 ) and ( 29 ) to said signal input part ( 34 ) and said signal output part ( 35 ), respectively; and the sources of said field effect transistors ( 16 ) and ( 28 ) forming said variable resistors ( 53 ) and ( 54 ) are connected to a base potential part (GND) via capacitors ( 18 ) and ( 30 ), respectively, and via said ground line ( 57 ).

16. A cellular mobile telephone terminal according to claim 14 , wherein said field effect transistor ( 21 ) forming said variable resistor ( 51 ) is chosen to have a threshold voltage higher than the threshold voltage of said field effect transistor ( 25 ) forming said variable resistor ( 52 ).

17. A cellular mobile telephone terminal according to claim 14 , wherein said field effect transistor ( 21 ) forming said variable resistor ( 51 ) is chosen to have a threshold voltage higher than the threshold voltage of said field effect transistor ( 25 ) forming said variable resistor ( 52 ) by a value corresponding to a gain control voltage range where said variable resistor ( 52 ) performs a linear gain control operation.

18. A cellular mobile telephone terminal according to claim 14 , wherein the values of voltages applied to said reference voltage application parts ( 31 ) and ( 33 ) are set so that a gain control voltage range where said variable resistors ( 53 ) and ( 54 ) perform a linear gain control operation becomes continuous with a gain control voltage range where said variable resistors ( 51 ) and ( 52 ) perform a linear gain control operation.

19. A cellular mobile telephone terminal according to claim 14 , wherein said variable resistors ( 51 ), ( 52 ), ( 53 ), and ( 54 ) are formed at least from field effect transistors ( 21 ), ( 25 ), ( 16 ), and ( 28 ) whose gates are connected to resistors ( 22 ), ( 26 ), ( 20 ), and ( 32 ), respectively, and wherein: the gates of said field effect transistors ( 21 ) and ( 25 ) forming said variable resistors ( 51 ) and ( 52 ) are connected to said gain control voltage application part ( 42 ) via said resistors ( 22 ) and ( 26 ), respectively, and via said gain control line ( 56 ); the gates of said field effect transistors ( 16 ) and ( 28 ) forming said variable resistors ( 53 ) and ( 54 ) are connected together via said resistors ( 20 ) and ( 32 ); a resistor ( 41 ) is inserted between the sources of said field effect transistors ( 21 ) and ( 25 ) forming said variable resistors ( 51 ) and ( 52 ); a resistor ( 39 ) is inserted between the source of said field effect transistor ( 25 ) forming said variable resistor ( 52 ) and a part ( 61 ) connected via said resistors ( 20 ) and ( 32 ) to the gates of said field effect transistors ( 16 ) and ( 28 ) forming said variable resistors ( 53 ) and ( 54 ); a resistor ( 40 ) is inserted between a base potential part (GND) and said part ( 61 ) connected via said resistors ( 20 ) and ( 32 ) to the gates of said field effect transistors ( 16 ) and ( 28 ) forming said variable resistors ( 53 ) and ( 54 ); said reference voltage application part ( 23 ) is connected to the source of said field effect transistor ( 25 ) forming said variable resistor ( 52 ); said variable resistors ( 51 ) and ( 52 ) are connected in series via a capacitor ( 24 ); the sources of said field effect transistors ( 16 ) and ( 28 ) forming said variable resistors ( 53 ) and ( 54 ) are connected to said gain control voltage application part ( 19 ) via said gain control line ( 56 ); the drains of said field effect transistors ( 16 ) and ( 28 ) forming said variable resistors ( 53 ) and ( 54 ) are connected via capacitors ( 17 ) and ( 29 ) to said signal input part ( 34 ) and said signal output part ( 35 ), respectively; and the sources of said field effect transistors ( 16 ) and ( 28 ) forming said variable resistors ( 53 ) and ( 54 ) are connected to said base potential part (GND) via capacitors ( 18 ) and ( 30 ), respectively, and via said ground line ( 57 ).